A cover covering an engine and an intake duct for introducing fresh air outside an engine room into a combustion chamber of the engine are provided in the engine room. The cover includes a top face cover portion covering the engine from above, and a side face cover portion covering the engine from the lateral side. The intake duct is disposed so as to be continuous to a side edge of the side face cover portion such that the intake duct covers the engine from the lateral side together with the side face cover portion.
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8. An air intake device for an engine, having a cover provided inside an engine room and covering the engine, and an intake duct for introducing fresh air outside the engine room into a combustion chamber of the engine, wherein
the cover comprises a top face cover portion covering the engine from above, and a side face cover portion covering the engine from a lateral side,
the intake duct is disposed so as to be continuous to a side edge of the side face cover portion such that the intake duct covers the engine from the lateral side together with the side face cover portion,
fresh air is introduced from the intake duct to the engine through an air cleaner,
a part of the top face cover portion is placed on the side face cover portion via a seal,
an intake pipe extends toward the engine from the air cleaner,
at a lower edge of the part of the top face cover portion and an upper edge of the side face cover portion, a cutout is formed, and
the intake pipe, which extends toward the engine from the air cleaner, passes through the cutout.
1. An air intake device for an engine, comprising:
a cover provided inside an engine room and covering the engine; and
an intake duct for introducing fresh air outside the engine room into a combustion chamber of the engine, wherein
the cover comprises a top face cover portion covering the engine from above, and a side face cover portion covering the engine from a lateral side,
the intake duct is disposed so as to be continuous to a side edge of the side face cover portion such that the intake duct covers the engine from the lateral side together with the side face cover portion,
the intake duct comprises an outside air introduction duct portion for introducing outside air from outside the engine room into the combustion chamber, and an inside air introduction duct portion for introducing inside air from inside the engine room into the combustion chamber,
the intake duct is configured as a composite duct in which the outside air introduction duct portion and the inside air introduction duct portion are connected to a single downstream duct portion, the single downstream duct portion having a downstream end connected to an air cleaner,
the engine room is provided in a front portion of a vehicle,
the air cleaner is disposed on a right outer side of the cover as viewed from a vehicle front side, and
the intake duct is disposed on an outside of the cover and on a front side of the air cleaner, and covers the engine from a right side.
2. The air intake device for an engine according to
the engine is a front intake and rear exhaust engine, and
the intake duct is disposed so as to be continuous to a side edge on a front side of the side face cover portion.
3. The air intake device for an engine according to
4. The air intake device for an engine according to
5. The air intake device for an engine according to
the outside air introduction duct portion has an upstream end that is provided with an outside air inlet open forward and having a horizontally long rectangular shape,
the inside air introduction duct portion has an upstream end that is provided with an inside air inlet open upward and having a horizontally long rectangular shape, and
the downstream duct portion has a downstream end having a connection port open rearward and connected to the air cleaner.
6. The air intake device for an engine according to
the outside air introduction duct portion, at a higher position than the inside air inlet of the inside air introduction duct portion, has a duct wall curved toward the inside air introduction duct portion side and extending forward diagonally across above the inside air inlet.
7. The air intake device for an engine according to
the side face cover portion comprises a right-side face cover portion covering the engine from the right side,
the intake duct comprises a protrusion protruding rearward and extending in an up-down direction,
the right-side face cover portion comprises a mounting piece protruding forward relative to an upper end of a front end edge of the right-side face cover portion, and
the mounting piece is fixed to an upper end of the protrusion of the intake duct by a clip having a retaining function as a fastening member.
9. The air intake device for an engine according to
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The present invention relates to an intake device for an engine.
It has been conventionally known that, in an engine room of a vehicle, an engine is covered with a cover member to keep the engine warm. For example, Patent Literature 1 discloses providing, in an engine room, a cylinder head-side thermal insulating cover composed of an upper wall covering a top face of an engine and a side wall covering both side faces of an upper portion of the engine in the vehicle width direction. The vehicle front side of the thermal insulating cover is supported on an upper end of a radiator shroud, and the vehicle rear side thereof is supported on a dash panel. Furthermore, Patent Literature 1 also discloses providing a cylinder block-side thermal insulating cover covering a face on the vehicle front side of a cylinder block, a face on the vehicle rear side of the cylinder block, both side faces of the cylinder block in the vehicle width direction, and substantially the entire oil pan.
Patent Literature 1: Japanese Patent Laid-Open No. 2017-180210
In a case where a cover member covering an engine is provided in an engine room, the layout of an intake duct leading fresh air to a combustion chamber of the engine becomes a problem. Normally, it is conceivable that an air cleaner is protruded outside the cover member and that the intake duct is disposed outside the cover member and connected to the air cleaner. It is recognized that Patent Literature 1 also adopts such a configuration. However, since the intake duct is disposed apart from the engine toward the outside of the cover member, it is difficult to secure a disposition space of the intake duct in the engine room, and in addition, normally, an intake passage also becomes long.
Thus, in a case where a cover covering an engine is provided as described above, the present invention suppresses outward spread of a space to be secured in an engine room for disposition of an intake duct, and also achieves shortening of an intake passage and downsizing of an intake device.
To solve the problem, in the present invention, an intake duct forms a part of a cover covering an engine from the lateral side.
An intake device for an engine disclosed herein has a cover provided inside an engine room and covering the engine, and an intake duct for introducing fresh air outside the engine room into a combustion chamber of the engine, wherein:
According to this, the intake duct is continuous to the side edge of the side face cover portion, so that the intake duct approaches the engine as compared with a case where the intake duct is disposed outside the side face cover portion. This prevents an increase in a space occupied by, in the engine room, the cover and air intake system components including the intake duct, facilitating the layouts of the cover and the air intake system components in the engine room.
Furthermore, the intake duct can be caused to approach the engine, so that an intake passage is prevented from becoming long. The intake duct has a function of covering the engine from the lateral side so that the side face cover portion can be made small accordingly. By the shortening of the intake passage and the downsizing of the side face cover portion as described above, the device is advantageously reduced in weight.
In an embodiment, the engine room is provided in a front portion of a vehicle,
In the front intake-type engine, the intake duct is disposed on the front side of the side face cover portion, so that it is advantageous in shortening the intake passage.
In an embodiment, the intake duct and the side face cover portion are coupled together by a fastening member. Thus, the intake duct can be used for support of the side face cover portion, which is advantageous in reducing the number of components and enhancing mounting stability of the side face cover portion.
In an embodiment, the fastening member is a clip having a retainer. Accordingly, coupling of the side face cover portion and the intake duct is facilitated.
According to the present invention, in a case where the cover including the top face cover portion covering the engine from above and the side face cover portion covering the engine from the lateral side are provided in the engine room, the intake duct is disposed so as to be continuous to the side edge of the side face cover portion such that the intake duct covers the engine from the lateral side together with the side face cover portion, so that the layouts of the cover and the air intake system components in the engine room are facilitated, the shortening of the intake passage is achieved, and in addition, the device is advantageously reduced in weight.
Hereinafter, a mode for carrying out the present invention will be described based on the drawings. The following description of a preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, applications thereof, or use thereof.
<Configurations of Engine and Peripherals>
Here, “the inside of the engine room 1” refers to a space defined when the opening on the upper side of the engine room 1 is blocked by closing the bonnet 3. In the present description, the advancing-receding direction of the vehicle is referred to as “the front-rear direction,” the advancing side is referred to as “the front side,” and the receding side is referred to as “the rear side.” Furthermore, the vehicle width direction is referred to as “the left-right direction.” Furthermore, “the right side” and “the left side” are when the vehicle is viewed from the front side.
The engine 2 includes a cylinder block 4 and a cylinder head placed on the cylinder block 4. An oil pan 5 is fixed to a bottom face of the cylinder block 4. Although not illustrated, a plurality of cylinders are formed inside the cylinder block 4. That is, the engine 2 is a multi-cylinder engine. A piston is slidably inserted into each cylinder. The piston is connected to a crankshaft via a connecting rod. The piston defines a combustion chamber of the engine 2 together with the cylinder and the cylinder head.
Fresh air is introduced into the combustion chamber of the engine 2 through an intake duct 11 and an air cleaner 12. The air cleaner 12 is a device that removes foreign matter such as dust or dirt contained in the fresh air to be introduced into the combustion chamber.
As illustrated in the same figure, the fresh air passes through an intake pipe 13 including a throttle valve from the air cleaner 12 and is introduced into a supercharger 14. The supercharger 14 increases the pressure of the fresh air to be introduced into the combustion chamber. The supercharger 14 of the present example is a mechanical supercharger that is driven via a belt by the crankshaft of the engine 2. Note that an electric supercharger or a turbocharger that is driven by exhaust energy may be adopted. The fresh air passing through the supercharger 14 is cooled by an intercooler 15 illustrated in
As illustrated in
The intake duct 11, the air cleaner 12, the intake pipe 13, the supercharger 14, the intercooler 15, the surge tank, and the intake manifold which form an air intake system of the engine 2 are disposed on the front side of the engine 2, and an exhaust manifold and an exhaust pipe continuing to the exhaust manifold which form an exhaust system of the engine 2 are disposed on the rear side of the engine 2. That is, the engine 2 is a front intake and rear exhaust engine.
<Cover Structure of Engine>
The heat storage cover 21 is provided in the engine room 1, covers the engine 2 from above the engine 2, and surrounds the periphery of an upper portion of the engine 2. Heat dissipated from the engine 2 is stored inside the heat storage cover 21 through the medium of air, and the heat storage cover 21 blocks at least a part of upward heat dissipation.
Here, “the inside of the heat storage cover” refers to the lower side of, in the heat storage cover, an inner face of a portion covering the engine from above, and the inside of, in the heat storage cover, an inner face of a portion at least partially surrounding the periphery of the engine.
The heat storage cover 21 includes, as illustrated in
A radiator 6 that cools cooling water of the engine 2 by heat exchange with air is disposed in front of the engine 2 so as to cover the engine 2 from the front side. A grille shutter 7 capable of blocking ventilation from the front side to the radiator 6 is provided in front of the radiator 6. The radiator 6 includes, on the back side, a radiator fan 8 that dissipates heat of the cooling water toward the engine 2. A front grille 9 is provided in front of the grille shutter 7.
The grille shutter 7 has a plurality of flaps 26 disposed at intervals in the up-down direction and includes an actuator that pivots each of the plurality of flaps 26. When the flaps 26 become horizontal as indicated by the chain line, ventilation from the front side to the radiator 6 is allowed, and when the flaps 26 become vertical as indicated by the solid line, the ventilation to the radiator 6 is blocked. When a passage switching mechanism of the intake duct 11, which will be described later, is operated and introduction of the fresh air into the combustion chamber of the engine 2 is brought into an inside air introduction state, in the grille shutter 7, the flaps 26 become vertical, thereby suppressing collision of vehicle traveling air against the radiator 6. As a result, heat dissipation from the engine room 1 to the front side is also suppressed.
Cooling water inflow hoses 27 and 28 (see
Here, the heat storage cover 21 blocks heat dissipation from the upper portion of the engine 2 to the upper side and the periphery, thereby contributing to keeping the engine 2 warm. On the other hand, the radiator 6 and the grille shutter 7 block heat dissipation from the engine 2 to the front side, thereby contributing to keeping the engine 2 warm. Furthermore, the radiator 6 emits the heat of the cooling water toward the engine 2 by using the radiator fan 8, thereby making heat storage of the heat storage cover 21 advantageous.
(Details of Heat Storage Cover)
As illustrated in
As illustrated in
As illustrated in
As illustrated in
Here, as illustrated in
As illustrated in
As illustrated in
<Disposition and Structure of Intake Duct>
As illustrated in
An upstream end of the outside air introduction duct portion 41 is provided with the outside air inlet 44 open forward and having a horizontally long rectangular shape. An upstream end of the inside air introduction duct portion 42 is provided with an inside air inlet 45 open upward and having a horizontally long rectangular shape. At a downstream end of the downstream duct portion 43, a connection port 46 connected to the air cleaner 12 is open rearward.
As illustrated in
In the intake duct 11, the mounting pieces 47 are fixed to a top face of the radiator shroud 20 illustrated in
(Cover Structure of Inside Air Inlet)
A part of the inside air inlet 45 of the inside air introduction duct portion is covered with the outside air introduction duct portion 41 from the top with a gap, and the remaining portion of the inside air inlet 45 is covered with the projection portion 51 from the top with a gap. Hereinafter, this cover structure will be described.
As illustrated in
As illustrated in
The outside air introduction duct portion 41 includes the projection portion 51 having a collar-like shape and protruding rearward above the inside air inlet 45 of the inside air introduction duct portion 42 from a rear face of the duct wall 41a. This projection portion 51 covers the remaining portion of the inside air inlet 45 from above. As illustrated in
From the viewpoint of prevention of entry of foreign matter, it is advantageous that an interval between the projection portion 51 and the inside air take-in port 45 is as narrow as possible. If it is desired to prevent entry of a bolt during assembly, it is conceivable that, for example, the interval between the projection portion 51 and the inside air take-in port 45 is set so as to be smaller than the diameter of an M6 nut. Note that if the interval is narrowed excessively, the projection portion 51 serves as a ventilation resistance and prevents inside air from being brought into the inside air take-in port 45. Accordingly, the interval between the projection portion 51 and the inside air take-in port 45 is preferably set in a range of, for example, 10 to 60 mm in comprehensive consideration of these problems. In the present embodiment, this interval is 40 mm.
(Passage Switching Mechanism of Intake Duct)
The passage switching mechanism of the intake duct 11 switches the introduction of the fresh air into the combustion chamber of the engine 2 between an outside air introduction state in which outside air outside the engine room 1 is introduced into the air cleaner 12 by the outside air introduction duct portion 41, and the inside air introduction state in which air in the engine room 1, in particular, hot air obtained by the heat storage cover 21, is introduced into the air cleaner 12 by the inside air introduction duct portion 42. Thus, the passage switching mechanism includes a first valve 61 and a second valve 62, which will be described later.
As illustrated in
As illustrated in
As described earlier, the outside air introduction duct portion 41 and the inside air introduction duct portion 42 branch from the downstream duct portion 43 and rise so as to be arranged in the left-right direction, and the first valve 61 and the second valve 62 are disposed at base ends of the rising of the outside air introduction duct portion 41 and the rising of the inside air introduction duct portion 42. That is, a first valve disposition portion of the outside air introduction passage 55 and a second valve disposition portion of the inside air introduction passage 56 are provided in parallel across a partition wall 58 separating both passages 55 and 56.
The first duct member 11A forms a part of the first valve disposition portion of the outside air introduction passage 55 and a part of the second valve disposition portion of the inside air introduction passage 56 in respective passage wall circumferential directions, and the second duct member 11B forms the remaining portions thereof in the passage wall circumferential directions.
The first valve 61 is a flap-type valve, and the second valve 62 is a butterfly-type valve. That is, both valves 61 and are rotation-type valves that rotate to open and close the passages, and are supported on one rotation shaft 63 extending over both of the outside air introduction duct portion 41 and the inside air introduction duct portion 42. Both valves 61 and 62 are positioned at a predetermined angle with respect to the rotation shaft 63 and supported so that, when either one of them is open, the other one is closed.
The rotation shaft 63 is supported on the second duct member 11B forming the rear portion of the intake duct 11, and an actuator 64 that rotationally drives the rotation shaft 63 is also supported on the second duct member 11B. That is, as illustrated in
In the present example, the shaft support portions 65 and are provided in opposing duct walls on the outside air introduction duct portion 41 side and on the inside air introduction duct portion 42 side in the second duct member 11B. The actuator support portion 67 is provided on an outside face on the outside air introduction duct portion 41 side in the second duct member 11B.
As described above, the rotation shaft 63 is supported on the second duct member 11B, so that the first valve 61 and the second valve 62 are also supported on the second duct member 11B by the second duct member 11B alone.
As illustrated in
As illustrated in
Outer circumferential faces of the fitting portions 73 to 77 in the first valve 61 and the second valve 62 are circular, while fitting holes thereof all have a square shape corresponding to the cross-sectional shape of the rotation shaft 63. The rotation shaft 63 is passed through the fitting holes of the fitting portions 73 to 77 of both valves 61 and 62, and both valves 61 and 62 are supported so as not to rotate with respect to the rotation shaft 63.
In a state in which the rotation shaft 63 is passed through the fitting portions 73 to 77 of the valves 61 and 62, the fitting portions 73 and 76 at both ends of the fitting portions 73 to 77 are fitted to the bushes 72 of the shaft support portions 65 and 66 and rotatably supported thereon. In other words, the rotation shaft 63 is rotatably supported on the bushes 72 of the shaft support portions 65 and 66 via the fitting portions 73 and 76 of the valves 61 and 62.
Axially opposed end portions of the fitting portion 74 of the first valve 61 and the fitting portion 75 of the second valve 62 which are axially adjacent to each other have a shape cut out in a semi-cylindrical shape, and the cutout portions are engagement portions 78 and 79. Both engagement portions 78 and 79 engage with each other in the valve rotation direction in a state in which the rotation shaft 63 is passed through the fitting portions 73 to 77, and regulate a relative position between the first valve 61 and the second valve 62 in the valve rotation direction.
That is, as illustrated in
The fitting portion 74 of the first valve 61 and the fitting portion 75 of the second valve 62 which are adjacent to each other are respectively provided with projections 82 and 83 protruding laterally for allowing a spacer 81 illustrated in
Hereinafter, specific description will be given. As illustrated in
In a state in which the first valve 61 and the second valve 62 are set in the second duct member 11B, the ridge 88 is fitted to the fitting groove 86, so that the spacer 81 is placed in the spacer receiver 85. At this time, as illustrated in
(Assembly of Intake Duct)
The bush 72 illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
Thereafter, the first duct member 11A and the second duct member 11B are welded together. Then, mounting of a cap 91 illustrated in
Note that the cap 91 and the actuator 64 may be first mounted on the second duct member 11B and then the first duct member 11A and the second duct member 11B may be welded together.
(Introduction of Air into Engine Combustion Chamber)
According to the embodiment, the first valve 61 and the second valve 62 are operated by the actuator 64 illustrated in
In the outside air introduction state, the air outside the engine room 1 illustrated in
The inside air introduction state will be described. Air around the engine 2 is warmed by the heat dissipated from the engine 2 and rises, and the air enters the inside of the heat storage cover 21. The heat storage cover 21 blocks the upward (bonnet 3 side) heat dissipation, so that the heat dissipated from the engine 2 is stored inside the heat storage cover 21 through the medium of air. As a result, the temperature of air inside the heat storage cover 21 or below the heat storage cover 21 becomes high.
The inside air inlet 45 of the intake duct 11 faces the inside of the heat storage cover 21 from the bottom, so that the high temperature air obtained by the heat storage cover 21 is brought into the inside air introduction passage 56 of the intake duct 11. Accordingly, the high temperature air is introduced into the combustion chamber of the engine 2 through the air cleaner 12, so that, for example, even when a large amount of air is required as in a lean combustion, a decrease in temperature of the combustion chamber is suppressed, which is advantageous in securing combustion stability of the engine 2.
In the embodiment, the radiator 6 illustrated in
Thus, as illustrated in
Note that the invention according to introduction of air into an engine combustion chamber is a technique useful for suppressing a decrease in temperature of the combustion chamber and is applicable not only to a lean combustion mode but also to a combustion mode in the vicinity of a so-called theoretical air-fuel ratio.
Furthermore, although the whole of an opening of the inside air inlet 45 of the embodiment faces the inside of the heat storage cover 21 from the bottom, a part of the opening may protrude outside the heat storage cover 21. The temperature of air becomes high in the vicinity of the heat storage cover 21 due to influence of the heat storage cover 21, so that, even in a case where a part of the inside air inlet 45 protrudes outside the heat storage cover 21 and air outside the heat storage cover 21 is partially brought into the intake duct 11, the high temperature air can be introduced into the engine combustion chamber.
(Layout of Intake Duct and the like)
According to the embodiment, as illustrated in
As illustrated in
Furthermore, the intake duct 11 has a function of covering the engine 2 from the right side, so that the right-side face cover portion 24 can be made small accordingly. Similarly, regarding the left-side face cover portion 25, the engine mount 38 has a function of covering the engine 2 from the left side, so that the left-side face cover portion 25 can be made small accordingly.
By the shortening of the inside air introduction passage 56 and the downsizing of the side face cover portions 24 and 25, which are described above, the device is advantageously reduced in weight.
The intake duct 11 and the right-side face cover portion 24 are coupled together by the clip 35 (fastening member), so that the coupling is facilitated and the intake duct 11 can be used for support of the right-side face cover portion 24, which is advantageous in reducing the number of components and enhancing mounting stability of the right-side face cover portion 24.
As illustrated in
On the other hand, while the inside air inlet 45 of the inside air introduction duct portion 42 is open upward, as illustrated in
Furthermore, the passage switching mechanism composed of the valves 61 and 62 and the like is provided inside the intake duct 11. The passage switching mechanism, in particular, the second valve 62, might be damaged by foreign matter entering the inside of the intake duct 11 from the inside air inlet 45. Accordingly, the upper side of the inside air inlet 45 is covered with the outside air introduction duct portion 41 so as to prevent entry of foreign matter into the inside air inlet 45, thereby preventing damage to the passage switching mechanism inside the intake duct 11 (in particular, the second valve 62) due to entry of foreign matter into the inside of the intake duct 11.
(Passage Switching Mechanism)
While the intake duct 11 is formed by welding of the first duct member 11A and the second duct member 11B, as illustrated in
As illustrated in
Furthermore, the relative position between both valves 61 and 62 in the valve axis direction is regulated by engagement of the projections 82 and 83 provided in the fitting portions 74 and 75 of both valves 61 and 62 with the spacer 81. Accordingly, the positions of both valves 61 and 62 in the respective valve disposition portions in the valve axis direction can be regulated only by, as described above, mounting the spacer 81 on the second duct member 11B in a state in which both valves 61 and 62 are engaged at the engagement portions 78 and 79.
As described above, according to the embodiment, by the simple configuration in which the engagement portions 78 and 79 and the projections 82 and 83 are provided in the fitting portions 74 and 75 of both valves 61 and 62 and in which the spacer 81 to be mounted on the second duct member 11B is provided, it is advantageous in assembling both valves 61 and 62 to the respective valve disposition portions with high accuracy, and it is advantageous in preventing malfunctions of the valves 61 and 62.
Nakagawa, Hiromasa, Kodama, Shin, Sugasaki, Kenji
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Sep 03 2019 | Mazda Motor Corporation | (assignment on the face of the patent) | / | |||
Feb 17 2021 | NAKAGAWA, HIROMASA | Mazda Motor Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 055510 | /0572 | |
Feb 18 2021 | KODAMA, SHIN | Mazda Motor Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 055510 | /0572 | |
Feb 18 2021 | SUGASAKI, KENJI | Mazda Motor Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 055510 | /0572 |
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